Variable temperature controlled soldering iron

ABSTRACT

A soldering iron system with automatic variable temperature control comprising a hand piece or robot arm including a soldering cartridge having a soldering tip, a coil that generates a magnetic field, and a temperature sensor for sensing a temperature of the soldering tip; a variable power supply for delivering variable power to the coil to heat the soldering tip; a processor including associated circuits for accepting a set temperature input and the sensed temperature of the soldering tip, and providing a control signal to control the variable power supply to deliver a suitable power to the coil to keep the temperature of the soldering tip at a substantially constant level of the set temperature input.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a Continuation-In-Part of U.S. patent application Ser. No. 16/365,279, filed Mar. 26, 2019, which is a Continuation-In-Part of U.S. patent application Ser. No. 15/450,425, filed Mar. 6, 2017, which is a Continuation-In-Part of patent application Ser. No. 15/333,590, filed on Oct. 25, 2016, which is Continuation of patent application Ser. No. 15/096,035, filed on Apr. 11, 2016, now U.S. Pat. No. 9,511,439, which is a Continuation of patent application Ser. No. 14/966,975, filed on Dec. 11, 2015, now U.S. Pat. No. 9,327,361, which is a Continuation-In-Part of patent application Ser. No. 14/794,678, filed on Jul. 8, 2015, now U.S. Pat. No. 9,516,762, which claims the benefit of U.S. Provisional Patent Application Ser. No. 62/033,037, filed on Aug. 4, 2014, the entire contents of all of which are hereby expressly incorporated by reference.

FIELD OF THE INVENTION

The disclosed invention relates generally to manufacturing, repair and rework of printed circuit boards (PCBs) using soldering, and more particularly to a soldering iron with automatic variable temperature control.

BACKGROUND

With the greater variety of components used on printed circuit boards (PCBs), smaller passive components and larger ICs with finer ball pitch dimensions, the demands on high quality solder joints to aid PCB assembly (PCBA) fabrication and rework have increased. Faulty solder joint has cost companies billions of dollars over the years. Many processes have been developed to reduce failure rate for wave solder systems. However, for point to point handheld soldering and rework applications, companies are relying on operators' skills to produce good solder joints with quality electrical connections. Regardless of how much training is provided to the operators of the soldering iron, without guidance during a soldering activity, the operators may make and repeat mistakes due to the fact that there are many factors that impact heat transfer by the soldering iron for forming a solder joint with good electrical connection. These factors include solder tip temperature, geometry of the solder tip, oxidation of the solder, human behavior, and the like.

Moreover, automatic (e.g., robotic) soldering is currently strictly an open-loop time based event, where a robot moves to the specific joint, the solder tip is automatically placed on the joint, solder is automatically applied, and a prescribed time later (determined by a specific software for the robot), the solder tip is automatically removed from the joint. This process is repeated until the robot's program is complete.

Heating of a soldering tip is typically performed by passing an (fixed) electric current from a power supply through a resistive heating element. However, different soldering applications require different heating temperatures. Since a single tip having a specific alloy is capable of producing heat at a certain (maximum) temperature, different soldering tips are needed for different heating applications. Simple soldering irons reach a temperature level determined by thermal equilibrium, dependent upon power (current) input and the materials of the workpiece, which it contacts with. However, the tip temperature drops when it contacts a large workpiece, for example, a large mass of metal and therefore a small soldering tip will lose significant temperature to solder a large workpiece. More advanced soldering irons have a mechanism with a temperature sensor to keep the tip temperature steady at a constant level by delivering more power to the tip, when its temperature drops.

Typically, a variable power control, which changes the equilibrium temperature of the tip without automatically measuring or regulating the temperature. Other systems use a thermostat, often inside the iron's tip, which automatically switches power on and off to the soldering cartridge/tip. A thermocouple sensor may be used to monitor the temperature of the tip and adjust power delivered to the heating element of the cartridge to maintain a desired constant temperature.

Another approach is to use magnetized soldering tips which lose their magnetic properties at a specific temperature (the Curie point). This approach depends on the electrical and metallurgical characteristics of a particular tip material. For example, the tip may include copper, which is a material with high electrical conductivity, and another magnetic material (metal) with high resistivity. As long as the soldering tip is magnetic, it closes a switch to the power supply and the heating element. When the temperature of the tip exceeds the required temperature (for the specific application), it opens the switch and thus the tip starts cooling until the temperature drops enough to restore magnetization of the tip material. The selection of a material with a fixed Currie point results in a heater that generates and maintain a specific, self-regulated temperature and the constant level and thus the heater requires no calibration. That is, when the heater temperature drops (when it contacts a thermal load), the power supply responds with sufficient power required to increase the tip temperature back to the fixed required temperature to correctly solder the workpiece. Again, a specific tip having a specific alloy with particular magnetization properties is capable of producing heat at or up to a certain temperature. Accordingly, different soldering tips are needed for different heating applications. This requires an inventory and maintenance of a variety of different soldering tips with different thermal characteristics. It also adds significant time to the soldering process of a workpiece large enough or with different types of components that require different tips since the operator has to keep changing the soldering tips.

SUMMARY OF THE INVENTION

In some embodiments, the disclosed invention is a soldering iron system with automatic variable temperature control. The soldering iron system includes a hand piece or robot arm including a soldering cartridge having a soldering tip, a heating coil and a temperature sensor for sensing a temperature of the soldering tip; a variable power supply for delivering variable power to the heating coil to heat the soldering tip; a processor including associated circuits for accepting a set temperature input and the sensed temperature of the soldering tip and providing a control signal to control the variable power supply to deliver a suitable power to the heating coil to keep the temperature of the soldering tip at a substantially constant level of the set temperature input.

In some embodiments, the disclosed invention is a soldering iron system with automatic variable temperature control. The soldering iron system includes a hand piece or robot arm including a soldering cartridge having a soldering tip, a heating coil and an impedance measuring device for measuring an impedance of the soldering tip; a variable power supply for delivering variable power to the heating coil to heat the soldering tip; a processor including associated circuits for accepting a set temperature input and the measured of the soldering tip, determining a temperature of the soldering tip from the measured impedance, and providing a control signal to control the variable power supply to deliver a suitable power to the heating coil to keep the temperature of the soldering tip at a substantially constant level of the set temperature input.

In some embodiments, the disclosed invention is a soldering iron system with automatic variable temperature control. The soldering iron system includes a hand piece or robot arm including a soldering cartridge having a soldering tip, a heating coil; a variable power supply for delivering variable power to the heating coil to heat the soldering tip; a processor including associated circuits for accepting a set temperature input and the measured of the soldering tip, determining an impedance of the soldering tip by turning off the power to the soldering tip and measuring the voltage of the coil, determining a temperature of the soldering tip from the measured impedance, and providing a control signal to control the variable power supply to deliver a suitable power to the heating coil to keep the temperature of the soldering tip at a substantially constant level of the set temperature input.

In some embodiments, the set temperature input is adjustable by an operator of the soldering iron system, or is automatically adjustable by the processor based on one or more of a cartridge type, a tip type, a tip size, a tip shape, a thermal load type or size, and a quality of a soldering joint being formed by the solder tip and determined by the processor.

In some embodiments, the processor determines the quality of the soldering joint by determining a thickness of an intermetallic component (IMC) of the soldering joint and determining whether the thickness of the IMC is within a predetermined range.

The automatic variable temperature control of the disclosed invention may be used in a handheld soldering iron or an automatic (robotic) soldering station for soldering work pieces.

During soldering process, the soldering joints may be soldered randomly. Soldering information data is collected for each soldering operation, but no soldering identification information is collected so it is not know which soldering joint is being worked on. Accordingly, another aspect of the invention involves an intelligent soldering hand piece comprising a housing; a solder tip; a heater for heating the solder tip; a processor for receiving an image of a solder joint being soldered by the intelligent soldering hand piece, determining solder joint information, and associating the image of the solder joint with the determined solder joint information to distinguish the determined solder joint information for each respective joint.

One or more implementations of the aspect described immediately above include one or more of the following: a camera is associated with the hand piece, the camera obtaining the image of solder joint being soldered; the hand piece includes a distal portion with the camera; the camera is an internal camera; the internal camera includes wiring and electronics internal to the housing; the camera is an external camera; the external camera includes wiring and electronics external to the housing; the processor receives an image of a solder joint being soldered before soldering of the solder joint occurs and receives an image of a solder joint being soldered after soldering of the solder joint occurs; the processor receives an image of a solder joint being soldered while soldering of the solder joint occurs; and/or the processor determines a thickness of an intermetallic compound (IMC) of a solder joint being formed by the solder tip, generates an indication signal indicating that a reliable solder joint connection is formed when the thickness of the IMC is within a predetermined range, and associates the image of the solder joint with the indication signal.

In some embodiments, the disclosed invention is a soldering iron system with automatic variable temperature control comprising a hand piece or robot arm including a soldering cartridge having a soldering tip, a coil that generates a magnetic field, and a temperature sensor for sensing a temperature of the soldering tip; a variable power supply for delivering variable power to the coil to heat the soldering tip; a processor including associated circuits for accepting a set temperature input and the sensed temperature of the soldering tip, and providing a control signal to control the variable power supply to deliver a suitable power to the coil to keep the temperature of the soldering tip at a substantially constant level of the set temperature input.

One or more implementations of the aspect described immediately above include one or more of the following: the temperature sensor is a temperature sensor for sensing a temperature of the soldering tip, and the processor includes associated circuits for accepting a set temperature input and the sensed temperature of the soldering tip, and providing a control signal to control the variable power supply to deliver a suitable power to the coil to keep the temperature of the soldering tip at a substantially constant level of the set temperature input; the control signal is a pulse width modulated signal to control the output power of the variable power supply; the set temperature input is adjustable by an operator of the soldering iron system; the set temperature input is automatically adjustable by the processor based on one or more of a cartridge type, a tip type, a tip size, a tip shape, a thermal load type or size, and a quality of a soldering joint being formed by the solder tip and determined by the processor; the processor determines the quality of the soldering joint by determining a thickness of an intermetallic compound (IMC) of the soldering joint and determining whether the thickness of the IMC is within a predetermined range; the processor generates an indication signal indicating that a reliable solder joint connection is formed when the thickness of the IMC is within the predetermined range, and transmits the indication signal; the coil receives a high frequency alternated electric current, generating electromagnetic induction to heat the soldering tip, which is an electrically conductive object, by eddy currents; the soldering cartridge includes a memory that stores a unique PID factor to maximize thermal performance; the soldering cartridge includes a plurality of soldering cartridges with each soldering cartridge of the plurality of soldering cartridges including a memory that stores a unique PID factor to maximize thermal performance; and/or the soldering iron system uses the temperature sensor to control different temperature set points.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1A depicts an exemplary handheld soldering iron, according to some embodiments of the disclosed invention.

FIG. 1B is an exemplary block diagram of a processor and associated components, according to some embodiments of the disclosed invention.

FIG. 1C depicts an exemplary handheld soldering iron where the processor and associated circuitry are in a power supply, according to some embodiments of the disclosed invention.

FIG. 1D shows an exemplary handheld soldering iron where the processor and associated circuitry are in a hand piece, according to some embodiments of the disclosed invention.

FIG. 1E illustrates an exemplary handheld soldering iron where the processor and associated circuitry are in a cartridge, according to some embodiments of the disclosed invention.

FIG. 1F shows an exemplary handheld soldering iron where the processor and associated circuitry are in a work stand, according to some embodiments of the disclosed invention.

FIG. 1G depicts an exemplary automatic soldering station, according to some embodiments of the disclosed invention.

FIG. 1H depicts an exemplary circuit for a soldering iron to variable control and set the soldering tip temperature, according to some embodiments of the disclosed invention.

FIG. 1I depicts an exemplary handheld soldering iron system, according to another embodiment of the disclosed invention.

FIG. 1J is a perspective view of an embodiment of a variety of components of a soldering iron of the handheld soldering iron system of FIG. 1I.

FIG. 1K is a perspective view of an embodiment of a soldering iron hand piece along with a variety of components of the handheld soldering iron system of FIG. 1I.

FIG. 2 shows an exemplary process flow, according to some embodiments of the disclosed invention.

FIG. 3A shows a graph for a change in temperature of a soldering tip over time, for three given load sizes, according to some embodiments of the disclosed invention.

FIG. 3B depicts a graph for a change in impedance of a soldering tip over time, for three given power levels and three given temperatures, according to some embodiments of the disclosed invention.

FIG. 4A illustrates a graph for the thickness of the IMC versus time, according to some embodiments of the disclosed invention.

FIG. 4B illustrates a graph for the thickness for the IMC versus soldering time, according to some embodiments of the disclosed invention.

FIG. 4C shows an IMC layer for a soldering event.

FIG. 5 is an exemplary process flow for liquidus detection and connection verification using images from a plurality of cameras, according to some embodiments of the disclosed invention.

FIGS. 6A-6D show various images used for detection of liquidus, according to some embodiments of the disclosed invention.

FIG. 7A shows some exemplary solder joints for through hole components, according to some embodiments of the disclosed invention.

FIG. 7B depicts some exemplary solder joints for surface mount components, according to some embodiments of the disclosed invention.

FIG. 8 shows an exemplary intelligent soldering cartridge, according to some embodiments of the disclosed invention.

FIG. 9 is a perspective view of another embodiment of a handheld soldering iron including a hand piece with a distal portion including an external camera.

FIG. 10 is a perspective view of a further embodiment of a handheld soldering iron including a hand piece with a distal portion including an internal camera.

DETAILED DESCRIPTION OF THE INVENTION

In some embodiments, the disclosed invention is a soldering station with automatic soldering connection validation. The soldering station includes a processor, such as a microprocessor or controller, memory, input/output circuitry and other necessary electronic circuitry to perform the soldering connection validation.

In some embodiments, the processor receives various characteristics of the solder joint and soldering station and performs a process of calculating the intermetallic compound (IMC) thickness of solder and PCB substrate to ensure a good solder joint is formed during a soldering event. Once a good electrical connection for the solder joint is confirmed, an audio, LED, or vibration indicator in the soldering station, for example, in a hand piece or on a display in a soldering station, informs the operator or a soldering robot program of the formation of the good solder joint. Typically, a good solder joint formed by SAC (tin-silver-copper) solder and copper substrate PCB is when the intermetallic thickness of the solder is between 1 um-4 um. Accordingly, if the soldering station uses, for example, SAC305 (96.5% Sn, 3% Ag, 0.5% Cu) solder wire with copper substrate PCB, the IMC thickness of the Cu₆Sn₅ is calculated by some embodiments of the disclosed invention and the operator or the robot is notified once the IMC thickness of the solder reaches 1 um-4 um, during the soldering event.

The chemical reaction between the copper substrate and the soldering can be shown as:

3Cu+Sn->Cu₃Sn (phase 1)  (1)

2Cu₃Sn+3Sn->Cu₆Sn₅(phase 2—IMC thickness is 1 um-4 um)  (2).

Phase 1 of the chemical reaction is temporary (transient) and therefore is not used for determination of the quality of the solder joint.

FIG. 1A depicts an exemplary handheld soldering iron, according to some embodiments of the disclosed invention. As shown, the handheld soldering iron includes a power supply unit 102 including a display 104, for example an LCD display, and various indicators 106, such as LED indicators 106 a and 106 b. Other indicators, such as sound-emitting devices or haptic devices can be used as well. The soldering iron further includes a hand piece 108 coupled to the power supply unit 102 and a (work) stand 110 that accommodates the hand piece 108. The hand piece 108 receives power from the power supply unit 102 and heats a soldering tip attached to or located in a soldering cartridge to perform the soldering on a work piece. In some embodiments, the soldering cartridge may include a temperature sensor thermally coupled to the soldering tip to sense the tip temperature and transmit that data to a processor.

The hand piece 108 may include various indicators such as one or more LEDs and/or a buzzer on it. In some embodiment, the power supply unit 102 or the hand piece 108 includes a microprocessor, memory, input/output circuitry and other necessary electronic circuitry to perform various processes. One skilled in the art would recognize that the microprocessor (or the controller) may be placed in the power supply, in the hand piece, or a stand of the soldering system. Communication with external devices, such as a local computer, a remote server, a robot for performing the soldering, a printer and the like, may be performed at the work stand by wired and/or wireless connections, using the known wired and/or wireless interfaces and protocols.

In some embodiments, the microprocessor and the associated circuits identify what soldering cartridge is being used, validate the tip geometry, validate that the temperature and load (solder joint) are matched to ensure that the selected soldering cartridge can produce sufficient energy to bring the load to the melting point of the solder, detect liquidus temperature and then determine the IMC thickness of the solder, as described in more detail below. For example, if the tip geometry is too small for the load, the tip would not be able to bring the joint to the solder melting point. The liquidus temperature is the temperature above which a material is completely liquid. Liquidus temperature is mostly used for impure substances (mixtures) such as glasses, alloys and rocks. Above the liquidus temperature the material is homogeneous and liquid at equilibrium. Below the liquidus temperature, crystals are formed in the material after a sufficient time, depending on the material.

FIG. 8 shows an exemplary intelligent soldering cartridge, according to some embodiments of the disclosed invention. In some embodiments, the intelligent soldering cartridge includes a soldering tip 802, associated wiring 804, a magnetic shield 806, a heater 808 to heat the tip, a shaft or housing 810, connector(s) 812 for both electrical and mechanical connections and a storage device 814 such as a non-volatile memory (NVM). The intelligent soldering cartridge may further include one or more sensors 818, such as temperature sensor to measure the temperature of the tip and/or a potentiometer to measure the impedance of the tip, a radio frequency identification device (RFID) 820, and/or a processor and associated circuitry 816 such as input/output circuits and wired and/or wireless interfaces to data communication. The mechanical connector (not shown) for connecting the cartridge to a hand-piece or robot arm may be included for efficient, quick-release operation.

In some embodiments, the cartridge ID, for example, a serial number or a code unique to the specific cartridge, is read from the NVM 814 or RFID 820 to identify the cartridge, its type and related parameters and specification information. The NVM 814 may also store information about a change in temperature of a plurality of soldering tips over time, similar to the graphs of FIGS. 3A, 3B, 4A and 4B. Once a specific soldering tip is used, the information about the change in temperature of the tip being used is retrieved form the NVM. Typically, during a soldering event, the temperature of the tip drops as it heats the solder joint and thus the heater needs to reheat the tip, which often results in overshooting the required (set) temperature for the tip. However, in some embodiments, a temperature sensor 818 periodically senses the temperature of the tip and feeds the information to the processor (or directly to the heater 808) to adjust the temperature in case of any temperature drop (or increase) due to the load or other factors. This way, an appropriate amount of heat is directly delivered to the solder joint.

In some embodiments, the NVM and/or the RFID stores data related to characteristics of the cartridge such as, part number, lot code, serial number, total usage, total point, tip mass/weight, tip configuration, authentication code (if any), thermal efficiency, thermal characteristic, and the like. This data may be retrieved by a processor (e.g., the internal processor 816 or an external processor) periodically at the startup and during the soldering operation. In some embodiments, the data may also be received and transmitted via wired or wireless methods.

In some embodiments, the NVM and/or the RFID of the cartridge includes all or some of the following information.

1. Temperature of the heater/tip and optionally information about a change in the temperature over time for various load sizes;

2. Tip geometry, which may include contact surface of the tip with the solder, distance of the tip from the heater, mass of the tip;

3. Thermal efficiency factor of the tip (based on mass, shape, heater, etc.);

4. Number of soldering events that have been performed by the specific tip, which may be used for traceability

5. Time of tip usage (for example, total time of the tip being usage for warranty and traceability)

6. Date of manufacturing of the cartridge

7. Serial number and identification code for the cartridge

8. Part-number

9. CV selection flag (whether the tip and/or cartridge is subject to CV technology)

10. Data Checksum

11. Different proportional-integral-derivative controller (“PID”) factors for each cartridge to maximize thermal performance

Tip temperature, tip geometry and thermal efficiency are used to calculate an approximation for the IMC layer thickness, as explained below. Number of soldering events, time of tip usage and date of manufacturing can be used to further refine the process of IMC thickness calculation, as explained below. The historical information, such as usage time, number of soldering events and the like may be written back to the NVM to be accumulated.

Serial number, part number and CV selection flag are for housekeeping, traceability and/or determination of whether the process will can/should provide a valid indication of the IMC formation. Data checksum may be used to determine if there is a failure in the NVM or communication data transfer error, in some embodiments. In some embodiments, the intelligent cartridge for a robot soldering station includes an anti-rotation D ring for preventing the cartridge from unwanted rotations, when the robot arm is being rotated.

In some embodiments, the intelligent soldering cartridge is capable of performing the processes of liquidus detection and connection verification according to both process flows of FIGS. 2 and 5. For example, the processor 816 is capable of retrieving the information about characteristics of the cartridge from the NVM or RFID, detecting liquidus occurrence at a solder joint, receiving a 3D current image of the solder joint, determining volume of the dispensed solder after occurrence of the liquidus from the 3D current image, comparing the volume of the dispensed solder to an amount of solder needed to fill in a barrel of a hole for a through hole component, or to fill in a surface of a barrel of a hole for a surface mount component to determine how much of the dispensed solder is dissipated onto the barrel or on the surface area of the barrel, repeating the comparing of the volume of the dispensed solder until the dispensed solder has filled the barrel or the surface area of the barrel, and generating an indication signal indicating that a reliable solder joint connection is formed when the dispensed solder has filled the barrel or the surface area of the barrel within a predetermined tolerance.

In addition, the processor 816 may be capable of retrieving the information about characteristics of the cartridge, detecting liquidus occurrence at a solder joint, receiving a 3D current image of the solder joint, determining volume of the dispensed solder after occurrence of the liquidus from the 3D current image, comparing the volume of the dispensed solder to an amount of solder needed to fill in a barrel of a hole for a through hole component, or to fill in a surface of a barrel of a hole for a surface mount component to determine how much of the dispensed solder is dissipated onto the barrel or on the surface area of the barrel. The processor may then repeat the comparing of the volume of the dispensed solder until the dispensed solder has filled the barrel or the surface area of the barrel, and generating an indication signal indicating that a reliable solder joint connection is formed when the dispensed solder has filled the barrel or the surface area of the barrel within the predetermined tolerance.

FIG. 1B is an exemplary block diagram of a processor and associated components, according to some embodiments of the disclosed invention. As illustrated, a processor 112, a memory 114 a non-volatile memory (NVM) 116 and an I/O interface 118 are coupled to a bus 120 to comprise the processor and associated circuitry of some embodiments of the disclosed invention. The I/O interface 118 may be a wired interface and/or a wireless interface to components external to the soldering station. Optionally, one or more cameras 122 and 124 are coupled to the processor and the memory via the bus 120 or the I/O interface 118 to capture images from a solder joint from various viewpoints. Additionally, an optional temperature sensor 126 for sensing the temperature of the soldering tip may be coupled to the processor 112 and the memory 114 via the bus 120 or the I/O interface 118. The optional temperature sensor may be located at or near the soldering tip.

As one skilled in the art would readily understand, different components depicted in FIG. 1B may be located in different parts of the soldering iron or automatic soldering station, as partly explained below. For example, the cameras may be located outside of and decoupled from the different components of the soldering iron or automatic soldering station, while the processor and associated circuitry may be located in any components of the soldering iron or automatic soldering station (as described below). The sensors may also be located in/at different components of the soldering iron or automatic soldering station, depending on their applications.

FIG. 1C depicts an exemplary handheld soldering iron where the processor and associated circuitry are in a power supply, according to some embodiments of the disclosed invention. As shown, the power supply unit includes the processor and associated circuitry and an internal power monitoring unit/circuit to detect and change the power supplied by the power supply to the hand piece, cartridge and/or the soldering tip. The power supply unit also includes wired and/or wireless interface(s) to electronically communicate with the hand piece, the LEDs, the cartridge and/or external devices. Once the processor determines the quality of the solder joint, it outputs an appropriate signal to activate one or more of an LED, a sound-emitting device, and a haptic device to notify the operator about the determined quality of the solder joint.

Moreover, the cartridge ID, for example, a serial number or a code unique to the specific cartridge, is read from the memory (e.g., NVM or RFID) of the cartridge to identify the cartridge and its type. This may be done by a wired or wireless connection. For instance, in the case of an RFID within the cartridge, the RFID (or even the NVM) may be read (by the processor) wirelessly. Once the intelligent soldering cartridge and its type are identified, the relevant parameters of the cartridge are retrieved by the processor from a memory, for example, an EEPROM. The memory that stores the cartridge related parameters may be in or outside of the cartridge. In some embodiments, if all of the related (cartridge) parameters are stored in a memory (which is in the cartridge), the cartridge may not need to be specifically identified since the parameters are already available in the memory of the cartridge and are specific to the cartridge.

In some embodiments, the cartridge may have a barcode, a magnetic stripe or a “smart chip” to identify the cartridge. Once the cartridge is identified, the relevant information may be read from the barcode, the magnetic stripe, the smart chip or fetched from an outside storage, such as a memory or a database coupled to a computer network, such as the Internet. For the purpose of the present application and the claimed invention, a storage device would also include a barcode, a magnetic stripe and a smart chip.

FIG. 1D shows an exemplary handheld soldering iron where the processor and associated circuitry are in the hand piece, according to some embodiments of the disclosed invention. The general functions and operations of these embodiments are similar to those explained with respect to FIG. 1C, except that the processor (and associated circuitry) and the power monitor unit/circuit are now located with the hand piece.

FIG. 1E illustrates an exemplary handheld soldering iron where the processor and associated circuitry are in a cartridge, according to some embodiments of the disclosed invention. In these embodiments, the cartridge may be similar to the intelligent cartridge depicted in FIG. 8 and explained above. The general functions and operations of these embodiments are similar to those explained with respect to FIG. 1C, except that the processor (and associated circuitry) and the memory are now located with the cartridge. Again, the communications between the cartridge, the hand piece and external devices may be wired and/or wireless. As one skilled in the art would readily recognize, the power monitoring unit/circuit (not shown) may be located in the power supply unit, the hand piece or the cartridge itself. In these embodiments, the devices that notify the operator (e.g., LEDs, sound-emitting device, and/or haptic devices) may be located with the hand piece or the cartridge itself If located with the hand piece, the hand piece includes a wired and/or wireless interface to communicate with the cartridge (and any relevant external devices).

FIG. 1F illustrates an exemplary handheld soldering iron where the processor and associated circuitry are in a cartridge, according to some embodiments of the disclosed invention. The general functions and operations of these embodiments are similar to those explained with respect to FIG. 1C, except that the processor (and associated circuitry) and the power monitor unit/circuit are now located with the work stand of the soldering iron.

FIG. 1G shows an exemplary automatic soldering station, according to some embodiments of the disclosed invention. In these embodiments, the hand piece and the cartridge are assembled on or part of a robot arm as shown. As shown, a robot arm 140 is capable of three-dimensional movements and rotations. A hand-piece 144 is coupled to the robot arm and an intelligent soldering cartridge, for example, an intelligent soldering cartridge according to FIG. 8 is connected to the hand-piece. In some embodiments, the intelligent soldering cartridge 142 may be directly coupled to the robot arm 140, which would be acting as the hand-piece.

A work piece 154, such as a printed wiring board (PWB), is placed on a moving platform 156 to have a soldering operation performed thereon. A solder feeder 146 provides solder to the work piece 154 via a grip, anchor, roller or tube 148. One or more cameras 152 placed at different angles capture the close up of the solder joint on the work piece. A power supply 150 provides power to the cartridge and related electronics therein.

This way, the CV technology of the disclosed invention is capable of providing feedback (a closed-loop system) to any conventional automatic soldering station. For example, the open-loop time based event of the conventional approaches is significantly improved by providing a real-time feedback of the solder quality. That is, instead of using a prescribed time for a solder joint, the CV technology provides the robot motion control system with a feedback signal that indicates when a good joint has been made. In some embodiments, only upon the indication of a good joint, the robot can move to the next joint in the program. When a bad joint has been made, the robot stops immediately or at the end of the program and alerts the operator of an issue with the solder joint.

FIG. 1H depicts an exemplary circuit for a soldering iron to variable control and set the soldering tip temperature, according to some embodiments of the disclosed invention. As shown, a variable power supply 162 delivers power to a coil 164 of a soldering hand piece or robot arm 164 to heat the coil. The heat of the coil 164 is then transferred to a soldering tip 166. The hand piece or robot arm164 includes a temperature sensor 172 to measure the temperature of the tip and/or an impedance measuring device 172, such as a potentiometer, to measure the impedance of the tip, according to the approaches described below. If a temperature sensor, the sensor may be a contact or non-contact sensor for measuring the temperature of the tip.

The temperature measurement information 167 and/or the impedance measurement information 168 are then received by a processor with associate circuitry and program 169. Additionally, temperature setting information 170 is also received by the processor 169. Based on the temperature setting information 170, the temperature measurement information 167 and/or the impedance measurement information 168, the processor 169 controls (via a control signal 171) the variable power supply 162 to deliver the required power, set by the temperature setting information 170 to the coil 164, so that the coil keeps a constant temperature at the set temperature. The output power of the variable power supply 162 may be varied based of a change in the its output voltage or a pulse width modulated (PWM) control signal 171. The well-known PWM regulates the output of the power supply 162 by switching the voltage delivered to the coil 164 with the appropriate duty cycle, which approximates a voltage (and a resulting tip temperature) at the desired level.

In some embodiments, the temperature setting information 170 is provided by an operator depending on required temperature for an application. In some embodiments, the temperature setting information 170 is automatically set and varied (adjustable) by the processor 169 depending on one or more of the cartridge type, the tip type, the tip size, the tip shape, the thermal load type or size, and the quality of the connection determined by the validation process described below.

This way, the same soldering tip may be used for different heating applications, resulting is a reduced inventory and maintenance of a variety of different soldering tips and soldering time of a large workpiece or with different types of components that require different tips.

With reference to FIGS. 1I-1K, an exemplary handheld soldering iron system 174 with automatic variable temperature control according to an embodiment of the disclosed invention will be described.

The soldering iron system 174 with automatic variable temperature control includes a hand piece 176 including a shaft 177 and soldering cartridge 178 having a soldering tip 180, a coil 182 to generate a magnetic field, a magnetic shield 183, and a temperature sensor or impedance measuring device 184 for sensing a temperature or measuring an impedance of the soldering tip 180. The soldering iron system 174 includes a RF variable power supply 186 for delivering variable power to the coil 182 to heat the soldering tip 180 by skin effect. A high frequency alternated electric current passes through the coil 182 to generate electromagnetic induction to heat tip 180, which is an electrically conductive object, by eddy currents. A (work) stand 187 accommodates the hand piece 176. A connector 188 with a chip including a processor and associated circuits accepts a set temperature input and a sensed temperature of the soldering tip 180 and provides a control signal to control the RF variable power supply 186 to deliver a suitable power to the heating coil 182 to keep the temperature of the soldering tip 180 at a substantially constant level of the set temperature input. A solder tip retainer 190 covers the solder tip 180.

In another embodiment, to make the handheld soldering iron system 174 more precise and powerful, each soldering cartridge 178 includes a memory (e.g., NVM 814, RFID 820) built in the cartridge 178 that stores different PID factors for each cartridge 178 to maximize thermal performance.

Instead of using curie point to get a fixed temperature, as was done with induction heating handheld soldering iron system(s) in the past, the handheld soldering iron system 174 uses the temperature sensor 184 to control different temperature set point(s) (i.e., any desired temperature set point). In the handheld soldering iron system 174, because of the instantaneous response of induction heating, controlling the heat using the soldering cartridge 178, which stores a unique PID factor in each different cartridge to outperform the traditional curie point fixed temperature and avoid excessive over shooting that damages electronic components, and based on sensed temperature, is advantageous over induction heating handheld soldering iron system(s) in the past, which used curie point to obtain a fixed temperature.

FIG. 2 shows an exemplary process flow, according to some embodiments of the disclosed invention. As shown in block 202, the process for validating all the connection joints between the component and the PCB substrate starts. In block 204, the cartridge being used is identified and the data related to the identified cartridge is retrieved from a non-volatile memory (NVM), such as an EEPROM, in the cartridge or outside of the cartridge. As described above, in some embodiments, the data related to the identified cartridge is retrieved, by the processor, from the NVM in the cartridge.

In block 206, the process (e.g., processor) checks the power level to determine whether any soldering action is being performed, within a period of time. If no soldering action to be performed yet, the process waits in block 206. For example, a timer can be set to a predetermined time and if no action happens within that time, the process waits. However, if a soldering action is to be performed, the process proceeds to an optional block 208, where the indicators are reset.

FIG. 3A shows a graph for a change in temperature of a soldering tip over time, for three given solder load sizes. As describe above, this data may be stored in the memory of the cartridge. Graph 306 is for a large load size (e.g., ˜104 Cu Mil²), graph 304 is for a medium load size (e.g., ˜54 Cu Mil²) and graph 302 shows a small load size (e.g., ˜24 Cu Mil²). As illustrated in FIG. 3A, for a given tip, the heavier the load, the higher temperature drop. In some embodiments, if the tip temperature drop is greater than a predetermined value, for example, around 25° C. (determined by experimental data), the process is aborted since the power supply would be unable to recover fast enough to continue delivering power to the tip to maintain the temperature of the tip, within the required time to complete the soldering event (e.g., 8 seconds).

In some embodiments, the temperature drop may be detected by measuring the impedance of the tip and then determining the tip temperature by Equation (3) below. The impedance may be measured by turning off the power to the cartridge/tip and measuring the voltage of the coil (in the cartridge) that is in thermal contact with the tip. The impedance of the tip would then be the voltage of the coil times an impedance weight factor (K in Equation (3)), which would depend on the tip type and is stored in a memory, for example, in the cartridge itself In some embodiments, a temperature sensor may be placed in the cartridge to directly read the temperature drop of the tip and communicate it to the microprocessor.

R _(imd) =+R _(max)/(1+[k*e{circumflex over ( )}(−T)])  (3).

Where, R_(imd) is the impedance value, R_(min) is a minimum value of the impedance, R_(max) is a maximum value of the impedance, K is a weight factor and T is delta temperature, that is the temperature difference between the tip and the load. The tip temperature drop is typically due to heat transfer from tip to load at the beginning and could vary from 6° to 48° depends on tip geometry, heater, and type of the tip. R_(min) is the minimum impedance value for the solder tip, before power is on at startup. R_(max) is the maximum impedance value for the solder tip, after power is on at startup for a predetermined amount of time, for example, after 2 seconds. These values are specific to the specific solder tip that is being used and are stored in a memory accessible by the processor.

FIG. 3B depicts a graph for a change in impedance of a soldering tip over time, for three given power levels that are delivered by the power supply unit to the soldering tip and three given temperatures of the soldering tip. As explained above, this data may also be stored in the memory of the cartridge. Graph 318 is for a small power, graph 312 is for a large power and graph 314 shows a medium power. Moreover, graph 310 is for a small, graph 316 is for medium temperature and graph 320 is for a large temperature.

In some embodiments, the temperature drop may be detected by defining a thermal efficiency factor for each given tip geometry and heater material (stored in a memory, in the cartridge or outside of the cartridge), as shown in Equation (4) below. If power draws higher than TE_factor, the system determines an abort in the process by, for example, turning on a red LED, activating a haptic device, or activating a sound-emitting device.

TE_factor=TipMass*TipStyle*HTR_factor*Const  (4),

where, TipMass is the copper weight (mg), which is 0.65 for a LongReach tip, 1 for a Regular tip, and 1.72 for a Power tip. TipStyle refers to the distance from the tip of tip to the heater in the cartridge. For example, according to data for some soldering tips currently available in the market, TipStyle is 20 mm for a “LongReach” tip, 10 mm for a “Regular” tip, and 5 mm for a “Power” tip. HTR_factor is the heater temperature times a factor (e.g., 0.01), which is given (predetermined), based on the type of the heater. Const=4.651*10⁻³ for all types of heaters. For instance, the HTR_factor may be 800F*0.01=8; 700F*0.01=7; 600F*0.01=6; or 500F*0.01=5 for various heater types. These parameter values may be stored in a memory (e.g., NVM) of the soldering iron, soldering station, or within the cartridge itself.

Referring back to FIG. 2, in block 210, a thermal efficiency check is performed to ensure that the tip geometry/temperature and the load are matched, based upon tip temperature drop within a predetermined time period, for example, the first 2-3 seconds of the soldering event (e.g., according to Equations (3) or (4), or a temperature sensor). For instance, there is a match when the max power after 2 seconds from the start of the soldering is less than or equal the thermal efficiency factor of the solder tip being used. The parameters may be retrieved from the NVM.

In some embodiments, the thermal efficiency check process monitors the heat transfer and power recovery of the soldering station with respect to the tip and the load. Each tip type has its own thermal characteristic, which is a function of the tip temperature, mass, and configuration/style. For various tip types, their thermal characteristic and efficiency factors (TEs) are stored in a memory in the cartridge or outside of the cartridge.

During the first period of time (e.g., 2-3 seconds), the power to the tip is measured (e.g., from the power supply) and compared with the TE of the tip. If the measured power is greater than a threshold value, for example, 95% +/−10% of TE factor, it means that the tip is too small or the load is too large, because they require a lot of power. In this case, the thermal efficiency check fails (210 a), the process is aborted in block 226 and optionally one or more indicators, for example, a red LED, a haptic device and/or a sound-emitting device, are turned on. If the thermal efficiency check passed (210 b), the process proceeds to the optional block 212 where a passing indicator, such as a green LED and/or a beep, is turned on to let the operator or the robot program know that the thermal efficiency check process has passed.

In block 214, the liquidus temperature is detected based on the following heat transfer equation.

ΔT=P*TR  (5),

where, ΔT is the tip temperature minus the load temperature, P is the (electrical) power level to the tip, and TR is the thermal resistance between the tip and the load that may be retrieved from the NVM.

Since load temperature continues to increase until it reaches equilibrium, ΔT decreases throughout the soldering action. Also, power to the tip increases when the soldering event first starts. Therefore, TR will be decreasing, as shown below. Once liquidus occurs, TR is stabilized and thus the power to the tip P now starts decreasing, as shown below. Accordingly, to detected liquidus temperature, the change state in the power delivered to the soldering tip is observed.

ΔT↓=P↑*TR↓

ΔT↓=P↓*TR˜

In block 216, it is checked to see if the power is at a peak and declining. If not, the process is timed out (216 a) and aborted in block 226. If the power to the tip, measured from the power supply, is at a peak and declining, the process proceed to block 218 to turn on an indicator, for example, an LED and/or a beep sound. When the power is at a peak and declining, it means that the solder event is at liquidus state.

In block 220, the thickness of the IMC is determined by the following equation.

IMC=1+(k*In(t+1))  (6),

where k is a weight factor for the type of solder being used (provided by the manufacturer of the solder and stored in the memory) and t is the sample/sensing interval time, for example 100 ms to determine the IMC thickness at a given time after liquidus. For example, K is constant with a value of 0.2173, t is 0.1 second, that is, IMC is calculated at 0.1 s intervals to avoid over shooting for small loads. That is, the tip cools as it heats the solder joint and as the heater tries to reheat the tip, the temperature may be overshooting from its set (desired) value. Typically, the thickness of the IMC may vary between 1-4 um.

Generally, the thickness of the IMC of the solder joint would be a function of time and temperature. When the temperature is at melting point of the solder load (e.g., at 220-240° C.), it does not have a substantial impact on the thickness of the IMC of the solder joint. Accordingly, Equation (6) is based on only time and a fixed temperature.

FIG. 4A illustrates a graph for the thickness of the IMC of the solder joint versus time, for the weighing factor k=0.2173, which is obtain by experimentation, using many solder joint and IMC thickness measurements. As depicted in FIG. 4A, the IMC thickness increases over time, based on experimental data.

Referring back to FIG. 2, block 222 checks to see whether within a predetermine amount of time (cooling period), the determined thickness of the IMC is within a predetermined range, for example, 1 um to 4 um. If it is, the processes proceeds to block 224, where the operator is informed. If the result of the test in block 222 is false, the process is timed out (222 b) and aborted in block 226.

In some embodiments, the invention provides the operator with an indication of successful or potential non-successful joint formation, along with the ability to collect the intermetallic joint information, and the operational parameters for that particular joint for post processing. Indication can be accomplished via visual means, audible means, and/or vibration of the hand piece.

For example, but not by way of limitation, FIGS. 9 and 10 illustrate embodiments of a camera 900, 910 for a soldering hand piece that may be used to obtain an image of a soldering joint to determine the joint being worked on because in the past joints were frequently soldered randomly and soldering information data would be collected for each soldering event, but without knowing which joint was being worked on. Like elements in FIGS. 9 and 10 to those shown and described herein will be shown/described with a like reference number, but with an “a” suffix. The subject matter shown and/or described with respect to FIGS. 1-8 is incorporated herein. For example, but not by way of limitation, the processor and associated components shown and/or described with respect to FIG. 1B is incorporated herein.

In the embodiment of FIG. 9, the camera 900 is an external camera that is carried by the hand piece 108 a at a distal portion 902 of the housing/shaft 810 a. The external camera 900 is coupled to the power supply unit 102 a via cord 920, adapter 930, and plug/connector 940. In alternative embodiments, the external camera 900 may be located other than the distal portion 902 of the housing/shaft 810 a. For example, but not by way of limitation, the external camera 900 may be mounted on a tri pod near the soldering activity (e.g., on work bench).

In the embodiment of FIG. 10, the camera 910 is an internal camera that is carried by the hand piece 108 a at the distal portion 902 of the housing/shaft 810 a, but unlike with the external camera 900, with the internal camera 910, all the wiring/electronics is internal to the shaft 810 a and/or the power supply unit 102 a. For example, but not by way of limitation, the internal camera 910 may be mounted on the power supply unit 102 a.

In use, the camera 900, 910 obtains an image of a joint before the soldering event and after the soldering event. The images are associated with one or more of the collected and/or determined soldering information (e.g., tip geometry, liquidus temperature, temperature of the heater/tip, information about a change in the temperature over time for various load sizes, tip geometry, which may include contact surface of the tip with the solder, distance of the tip from the heater, mass of the tip, thermal efficiency factor of the tip (based on mass, shape, heater, etc.), number of soldering events that have been performed by the specific tip, which may be used for traceability, time of tip usage (for example, total time of the tip being usage for warranty and traceability), date of manufacturing of the cartridge, serial number and identification code for the cartridge, part-number, CV selection flag (whether the tip and/or cartridge is subject to CV technology), Data Checksum, detecting liquidus occurrence at a solder joint, receiving a 3D current image of the solder joint, determining volume of the dispensed solder after occurrence of the liquidus from the 3D current image, comparing the volume of the dispensed solder to an amount of solder needed to fill in a barrel of a hole for a through hole component, or to fill in a surface of a barrel of a hole for a surface mount component to determine how much of the dispensed solder is dissipated onto the barrel or on the surface area of the barrel, indication signal indicating that a reliable solder joint connection is formed) shown and/or described herein for each joint so that one can distinguish the collected/determined soldering information for each respective joint. Alternatively, the camera 900, 910 obtains an image of the joint during the soldering event or obtains an image of the joint before, during, and/or after the soldering event.

A debug mode (block 228) is used, for example, by a process engineer to keep track of the steps involved during a solder event. To enter the debug mode, a user needs to turn the debug mode on.

A similar process for detection of the liquidus may be used for removal of the solder from the solder joint to make sure that all of the solder is removed from the joint. For example, once the liquidus temperature is detected, a vacuum (machine) is turned on (automatically or manually) to remove the solder from the joint. This way, the vacuum machine is turned on at the right time. Because if it is turned on sooner than the liquidus temperature, the solder is not in a liquid state and thus cannot be removed. Also, if the vacuum is turned on before the liquidus temperature, most of the heat being applied to the joint is sucked out by the vacuum.

FIG. 4B illustrates a graph for the thickness for the IMC versus soldering time. As depicted, graph 402 is for a temperature of 300° C. with Y=0.176X+1.242, graph 404 is for a temperature of 275° C. with Y=0.044X+1.00, and graph 404 is for a temperature of 220° C. with Y=0.049X+0.297, where X is the time and Y is the IMC thickness. The constant numbers are derived from multiple experimentations. As shown, a break out of the IMC thickness happens at three different temperature ranges. Since the thickness of the IMC is a function of time and temperature, as temperature rises, the IMC grows larger, as a linear function. Depending on the application, any of these curves may be used to determine the weighing factor, K, in Equation (6). For example, for a soldering application with SAC305 tip (the specification of which may be stored in the NVM of the cartridge), graph 404 is used.

FIG. 4C shows an IMC layer with a scale of 10 um. The vertical arrows are where the IMC thickness measurement may be performed. As described above, the disclosed invention detects liquidus temperature, determines the thickness of the IMC and ensures that a desired thickness is achieved.

This way, the embodiments of the disclosed invention ensure a good bonding and electrical connection between two metals by calculating the intermetallic thickness and therefore prevent a bad joint in early stages. Moreover, the invention provides instant feedback (by the indicators) to operators on joint quality and process issues and thus the operators have the ability to track information on joint quality for post analysis. The operators can change or select from a menu different parameters to meet certain application requirements.

In some embodiments, when a self-regulated temperature feedback technology is utilized, there is no requirement for calibration of the system at customer site. The invention also provides the capability to help the operators to identify whether they are using an improper tip/cartridge combination for a soldering event. For example, the invention is capable of informing the operator (e.g. Via LED, sound-emitting device, haptic device, etc.), when the solder tip is not capable to deliver sufficient energy required to bring the load to a melting point after a predetermined time (e.g., 2 seconds) from the startup based on the thermal efficiency threshold stored in NVM.

In some embodiments, the invention uses at least two high resolution cameras to capture two or more 2D images, obtain a 3D image from those 2D images (utilizing various known techniques), use the 2D and 3D images to detect liquidus stage and then calculate the amount of solder filled through the via hole (barrel) for through hole components, or the amount solder spread out around the components for surface mount components.

FIG. 5 is an exemplary process flow for liquidus detection and connection verification using images from a plurality of cameras, according to some embodiments of the disclosed invention. In some embodiments, at least two high resolution cameras are placed close to the solder joint at two different locations to capture 2D images of the solder joint from two views (angles), before and after the soldering event. The liquidus is detected from comparison of the 2D images. Then, in the case of through hole components, the volume of the through hole barrel (barrel) is determined from 3D images generated from the 2D images. In the case of surface mounted (SMT) components, the surface of the barrel on the PCB is determined from the 2D images. As shown in block 502, two images of the soldering area (joint) are captured by the two cameras, before the soldering event to generate two reference images, as depicted in FIG. 6A. In block 504, a 3D reference image of the soldering area is generated from the two reference images, before the soldering event, by well know methods.

In block 506, the volume of the barrel V_(b) for through hole and/or the surface area of the barrel S_(b) for SMT component are determined from the 3D reference image to determine how much solder is need to fill the barrel or the surface area of the barrel. The surface of the barrel may also be determined from the 2D images, depending on the cameras positions. For example, knowing the distance and the angle of each camera to the solder joint, the distance of any point (e.g., points on the perimeter of the barrel surface) may be determined, using simple known trigonometry. Also, having a second (stereo) camera, provides at lea four points to be used for volume determination. There are also known software tools (e.g., computer vision software) that are capable of measuring the volume (and surface areas) from 3D images. For example, Image-Pro Premier 3D™ and Image-Pro PIus™ from MediaCybernetics™ is capable of measuring the properties of multiple materials within a volume and easily discover percent composition, material mass, orientation, diameter, radii, and surface areas. The tool is capable of measuring object volume, box volume, depth, diameter, radii, and surface area. Several other tools with similar functionalities are also available and know to one skilled in the art.

Accordingly, the amount of solder needed to fill in the barrel or the surface of the barrel is determined, depending on the type of the component. Immediately after the soldering event is started, two current images of the soldering area is captured, in block 508. In block 510, the color value of each pixel in the 2D reference images is compared to color value of each corresponding pixel in the 2D current images, as the soldering event progresses, to detect any color changes of the pixels in the current images due to spread of the solder. Since the pixel value of the solder color is known, this the process can determine whether a pixel is a solder pixel, i.e., contains solder, as shown in FIG. 6B.

In block 512, the processes in blocks 508 (FIG. 6C) and 510 are repeated until all the pixels in the current images are determined to be pixels of the dispensed solder, that is, the liquidus is now detected, as depicted in FIG. 6D. The process in block 512 is timed out after a predetermined amount of time (e.g., 8 seconds), if not all the pixels in the current images are determined to be pixels of solder. When all the pixels in the last two current images are determined to be pixels of the dispensed solder (within a tolerance range), the liquidus is detected, in block 514.

After the detection of the liquidus, the last current image from each camera are processed to generate a 3D current image, in block 516. Then, the volume of the dispensed solder V_(s) is determined from the 3D current image, by one or more of Equations (7) to (9), in block 518. In block 520, the calculated volume of the dispensed solder V_(s) is compared to the determined amount of solder needed to fill in the barrel (i.e., V_(b)) or the surface area of the barrel (i.e., S_(b)) to determine how much of the dispensed solder is dissipated into the barrel or on the surface area of the barrel. This process (block 520) is repeated in block 522, until the dispensed solder has filled the barrel or the surface area of the barrel. That is, the volume of the visible dispensed solder has reached (V_(s) Vb) or (V_(s) S_(b)), within a predetermined tolerance range. The process in block 522 is timed out after a predetermined amount of time (e.g., 8 seconds). An indicator (e.g., a LED and/or beep) is then turn on to notify the operator that the connection is now formed by filling all of the barrel or the surface of the barrel with the dispensed solder.

In other words, in the case of a through hole component, when the calculated volume reduces to a predetermined amount that is needed to fill the barrel and within a pre-defined tolerance for through hole component, a good solder joint is formed, as shown in FIG. 7A. In some embodiments, the calculation of the height and volume of the solder joint is performed based on the following equations.

V_(lead)=πr_(lead) ²h  (7)

V_(barrel)=πr_(barrel) ²h  (8)

V _(required)=πh(r _(barrel) ² h−r _(lead) ² h)  (9)

Where, V_(lead) is the volume of component lead; V_(barrel) is the volume of through hole barrel; V_(required) is the volume of solder required to fill the barrel, r_(lead) is the (though hole) component lead radius; r_(barrel) is through hole barrel radius; and h is the board thickness, as shown in FIG. 7A.

FIG. 7A shows some exemplary solder joints, the image of which is captured by the two cameras, for through hole components, according to some embodiments of the disclosed invention. FIG. 7B shows some exemplary solder joints, the image of which is captured by the two cameras, for surface mount components, according to some embodiments of the disclosed invention. In this case, the invention compares the height of the entire load to a predetermined reference height (a desired height) to form a parabolic or linear shape. Once the identified shape area is equivalent to a predefined percentage of the load (barrel) surface area within a predefined tolerance, a good solder is formed for the surface mount component. As shown in FIG. 7B, for a larger surface mount component, the solder joint is formed on the side of the component as a parabolic shape. However, for a smaller surface mount component, the solder joint is formed on the side of the component as a linear shape since the camera can only capture a linearly filled area due to the small size of the component.

A similar process for detection of the liquidus may be used for removal of the solder from the solder joint to make sure that all of the solder is removed from the joint. For example, once the liquidus temperature is detected using the above process, a vacuum (machine) is turned on (automatically or manually) to remove the solder from the joint. This way, the vacuum machine is turned on at the right time.

It will be recognized by those skilled in the art that various modifications may be made to the illustrated and other embodiments of the invention described above, without departing from the broad inventive step thereof. It will be understood therefore that the invention is not limited to the particular embodiments or arrangements disclosed, but is rather intended to cover any changes, adaptations or modifications which are within the scope and spirit of the invention as defined by the appended claims. 

I claim:
 1. A soldering iron system with automatic variable temperature control comprising: a hand piece or robot arm including a soldering cartridge having a soldering tip, a coil that generates a magnetic field, and a temperature sensor for sensing a temperature of the soldering tip; a variable power supply for delivering variable power to the coil to heat the soldering tip; a processor including associated circuits for accepting a set temperature input and the sensed temperature of the soldering tip, and providing a control signal to control the variable power supply to deliver a suitable power to the coil to keep the temperature of the soldering tip at a substantially constant level of the set temperature input.
 2. The soldering iron system of claim 1, wherein the temperature sensor is a temperature sensor for sensing a temperature of the soldering tip, and the processor includes associated circuits for accepting a set temperature input and the sensed temperature of the soldering tip, and providing a control signal to control the variable power supply to deliver a suitable power to the coil to keep the temperature of the soldering tip at a substantially constant level of the set temperature input.
 3. The soldering iron system of claim 1, wherein the control signal is a pulse width modulated signal to control the output power of the variable power supply.
 4. The soldering iron system of claim 1, wherein the set temperature input is adjustable by an operator of the soldering iron system.
 5. The soldering iron system of claim 1, wherein the set temperature input is automatically adjustable by the processor based on one or more of a cartridge type, a tip type, a tip size, a tip shape, a thermal load type or size, and a quality of a soldering joint being formed by the solder tip and determined by the processor.
 6. The soldering iron system of claim 5, wherein the processor determines the quality of the soldering joint by determining a thickness of an intermetallic compound (IMC) of the soldering joint and determining whether the thickness of the IMC is within a predetermined range.
 7. The soldering iron system of claim 5, wherein the processor generates an indication signal indicating that a reliable solder joint connection is formed when the thickness of the IMC is within the predetermined range, and transmits the indication signal.
 8. The soldering iron system of claim 1, wherein the coil receives a high frequency alternated electric current, generating electromagnetic induction to heat the soldering tip, which is an electrically conductive object, by eddy currents.
 9. The soldering iron system of claim 1, wherein the soldering cartridge includes a memory that stores a unique PID factor to maximize thermal performance.
 10. The soldering iron system of claim 1, wherein the soldering cartridge includes a plurality of soldering cartridges with each soldering cartridge of the plurality of soldering cartridges including a memory that stores a unique PID factor to maximize thermal performance.
 11. The soldering iron system of claim 10, wherein the soldering iron system uses the temperature sensor to control different temperature set points. 